IMPT of head and neck cancer: unsupervised machine learning treatment planning strategy for reducing radiation dermatitis

Noufal Manthala Padannayil; Dayananda Shamurailatpam Sharma; Sapna Nangia; Kartikeshwar C. Patro; Utpal Gaikwad; Nagarjuna Burela

doi:10.1186/s13014-023-02201-y

Radiation Oncology (Jan 2023)

IMPT of head and neck cancer: unsupervised machine learning treatment planning strategy for reducing radiation dermatitis

Noufal Manthala Padannayil,
Dayananda Shamurailatpam Sharma,
Sapna Nangia,
Kartikeshwar C. Patro,
Utpal Gaikwad,
Nagarjuna Burela

Affiliations

Noufal Manthala Padannayil: Department of Medical Physics, Apollo Proton Cancer Centre
Dayananda Shamurailatpam Sharma: Department of Medical Physics, Apollo Proton Cancer Centre
Sapna Nangia: Department of Radiation Oncology, Apollo Proton Cancer Centre
Kartikeshwar C. Patro: Department of Medical Physics, Apollo Proton Cancer Centre
Utpal Gaikwad: Department of Radiation Oncology, Apollo Proton Cancer Centre
Nagarjuna Burela: Department of Radiation Oncology, Apollo Proton Cancer Centre

DOI: https://doi.org/10.1186/s13014-023-02201-y
Journal volume & issue: Vol. 18, no. 1
pp. 1 – 9

Abstract

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Abstract Radiation dermatitis is a major concern in intensity modulated proton therapy (IMPT) for head and neck cancer (HNC) despite its demonstrated superiority over contemporary photon radiotherapy. In this study, dose surface histogram data extracted from forty-four patients of HNC treated with IMPT was used to predict the normal tissue complication probability (NTCP) of skin. Grades of NTCP-skin were clustered using the K-means clustering unsupervised machine learning (ML) algorithm. A new skin-sparing IMPT (IMPT-SS) planning strategy was developed with three major changes and prospectively implemented in twenty HNC patients. Across skin surfaces exposed from 10 (S10) to 70 (S70) GyRBE, the skin's NTCP demonstrated the strongest associations with S50 and S40 GyRBE (0.95 and 0.94). The increase in the NTCP of skin per unit GyRBE is 0.568 for skin exposed to 50 GyRBE as compared to 0.418 for 40 GyRBE. Three distinct clusters were formed, with 41% of patients in G1, 32% in G2, and 27% in G3. The average (± SD) generalised equivalent uniform dose for G1, G2, and G3 clusters was 26.54 ± 6.75, 38.73 ± 1.80, and 45.67 ± 2.20 GyRBE. The corresponding NTCP (%) were 4.97 ± 5.12, 48.12 ± 12.72 and 87.28 ± 7.73 respectively. In comparison to IMPT, new IMPT-SS plans significantly (P < 0.01) reduced SX GyRBE, gEUD, and associated NTCP-skin while maintaining identical dose volume indices for target and other organs at risk. The mean NTCP-skin value for IMPT-SS was 34% lower than that of IMPT. The dose to skin in patients treated prospectively for HNC was reduced by including gEUD for an acceptable radiation dermatitis determined from the local patient population using an unsupervised MLA in the spot map optimization of a new IMPT planning technique. However, the clinical finding of acute skin toxicity must also be related to the observed reduction in skin dose.

Published in Radiation Oncology

ISSN: 1748-717X (Online)
Publisher: BMC
Country of publisher: United Kingdom
LCC subjects: Medicine: Medicine (General): Medical physics. Medical radiology. Nuclear medicine; Medicine: Internal medicine: Neoplasms. Tumors. Oncology. Including cancer and carcinogens
Website: https://ro-journal.biomedcentral.com/

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